Wind Design Procedures for Wood Roof Trusses of Low-Rise Structures

Abstract Wind design procedures for wood roof trusses of low-rise structures are evaluated in this paper using wind tunnel test data and two-dimensional finite-element frame models. The adequacy of the conventional and two alternative design procedures is determined by computing the combined stress...

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Published in:Journal of architectural engineering 2020-09, Vol.26 (3)
Main Authors: Hoq, S. M. Ashfaqul, Judd, Johnn P
Format: Article
Language:English
Subjects:
Adequacy
Combined stress
Design wind speed
Finite element method
Reliability aspects
Static loads
Technical Papers
Trusses
Two dimensional models
Wind forces
Wind speed
Wind tunnel testing
Wind tunnels
Wood construction
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description Abstract Wind design procedures for wood roof trusses of low-rise structures are evaluated in this paper using wind tunnel test data and two-dimensional finite-element frame models. The adequacy of the conventional and two alternative design procedures is determined by computing the combined stress index in the top chord and the reliability index, β conditioned on the occurrence of the design wind speed. For trusses with typical design dead loads and constructed with wood that exhibits a relatively low degree of variability in material design values, the results indicate that both the conventional and the alternative design procedures considered in this study meet a target reliability index equal to 3.0. Of the three procedures, replacing main wind force resisting system (MWFRS) loads on a chord segment with components and cladding (C&C) loads, while maintaining MWFRS loads on all other chord member segments, provides the closest match to the target β. For trusses constructed with wood that exhibits a relatively high degree of variability in material design values, the reliability index is lower for all design procedures.
doi_str_mv 10.1061/(ASCE)AE.1943-5568.0000425
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Of the three procedures, replacing main wind force resisting system (MWFRS) loads on a chord segment with components and cladding (C&amp;C) loads, while maintaining MWFRS loads on all other chord member segments, provides the closest match to the target β. 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source American Society Of Civil Engineers ASCE Journals
subjects Adequacy
Combined stress
Design wind speed
Finite element method
Reliability aspects
Static loads
Technical Papers
Trusses
Two dimensional models
Wind forces
Wind speed
Wind tunnel testing
Wind tunnels
Wood construction
title Wind Design Procedures for Wood Roof Trusses of Low-Rise Structures
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